Fibre-optic measurement device, rate gyro, and inertial stabilisation and navigation unit

ABSTRACT

A fiber-optic measurement device ( 10 ) includes a SAGNAC ring interferometer ( 20 ) having a proper frequency f p , a detector ( 14 ) and a modulation chain ( 30 ) generating a phase-shift modulation φ m (t) between the two counter-propagating waves ( 24, 25 ) propagating in the ring interferometer. The device aims to reduce measurement faults due to the linearity defects in the modulation chain of such a measurement device with optical fiber. For this reason, the fiber-optic measurement device reduces the amplitude of the phase-shift modulation φ m (t) which is the sum of a first biasing phase-shift modulation component φ b1 (t) and a first counter-reaction phase-shift modulation component φ cr1 (t), the phase-shift modulation φ m (t) falling or rising by twice the amplitude of the first biasing phase-shift modulation component φ b1 (t). A rate gyro including such a measurement device and an inertial stabilization or navigation unit including at least one such rate gyro are also described.

BACKGROUND OF THE INVENTION

The invention relates to a fiber-optic measurement device allowing to measure the variation of a parameter that produces non-reciprocal disturbances in a SAGNAC ring interferometer.

DESCRIPTION OF THE RELATED ART

The SAGNAC interferometer and the physical phenomena involved thereby are well known. Reference may be made for example about that to “The Fiber-Optic Gyroscope”, H. Lefèvre (Artech House, 1993).

In such an interferometer, a splitting plate or any other splitting device splits an incident wave at the input of the interferometer into two waves. The two thus-created waves are referred to as “counter-propagating waves”. They indeed propagate in opposite directions along a same closed optical path, then recombine with each other, producing interferences. The interference state between the two counter-propagating waves then depends on the relative phase difference between them. The luminous power P measured at the output of a SAGNAC interferometer is of the form: P(Δφ)=P₀[1+cos (Δφ)], where Δφ is the relative phase difference between the two counter-propagating waves. Hence, the power measured at the output of the interferometer takes values between a minimum (it is then talked about “dark” fringe) and a maximum (“bright” fringe) as a function the value of the phase difference Δφ.

It is known that some physical phenomena are liable to introduce so-called non-reciprocal phase shifts in the counter-propagating waves, hence generating a phase difference Δφ_(p) between these waves and modifying the interference state during the recombination thereof. Hence, the measurement of this non-reciprocal phase difference Δφ_(p) allows to quantify the phenomenon that has been generated thereby.

The main physical phenomenon liable to create non-reciprocal disturbances is the SAGNAC effect produced by the rotation of the interferometer about an axis perpendicular to the plane of its closed optical path. A second effect, the FARADAY effect or collinear magneto-optic effect, is also known for producing non-reciprocal effects of this type.

It is known that a SAGNAC interferometer can include a fiber-optic coil, which is preferably single-mode and of the polarization-maintaining type. The multiple turns of an optical fiber form a closed optical path of very long length, up to several kilometers.

A proper frequency f_(p) of the SAGNAC interferometer is commonly defined. The proper frequency f_(p) of a SAGNAC ring interferometer including a single-mode fiber-optic coil (silica fiber having a refractive index close to 1.5 in the operating wavelength range) of 1 kilometer long is of the order of 100 kilohertz (kHz). The extension of the coil length and hence of the optical path has for advantage to provide the interferometer with a greater sensitivity.

As explained hereinabove, the signal measured at the output of the interferometer is a cosine function of the phase difference Δφ between the two counter-propagating waves, so that the sensitivity of the response P(Δφ) of the interferometer near the zero phase difference (Δφ=0) is low.

It is known that it is possible to displace the operating point of the interferometer towards a point offering a greater sensitivity. It has notably been proposed to introduce an additional so-called “biasing” phase-difference modulation, by means of a phase modulator placed in the SAGNAC ring interferometer.

A simple-to-implement solution to perform this biasing is shown in FIG. 2. It consists in a square pulse-wave periodic modulation φ_(b0), at a biasing modulation frequency f_(b), having levels +π/2a₀ and −π/2a₀ (a₀ being a non-zero real number). This biasing phase-shift modulation φ_(b0) introduces between the two counter-propagating waves a biasing phase-difference modulation Δφ_(b0), which is also a pulse-wave modulation, at a biasing modulation frequency f_(b), with levels +π/a₀ and −π/a₀.

By choosing for example a₀=2, the response provided by the SAGNAC interferometer may be exploited with a very high sensitivity.

It is also known that the measurement accuracy is improved by the use of a so-called “phase cancellation” method, also called closed-loop operation, instead of a simple open-loop operation.

According to this method, an additional so-called “feedback” phase shift φ_(cr0) is generated by means of the phase modulator between the two counter-propagating waves. This additional phase shift then introduces between the two counter-propagating waves a feedback phase difference Δφ_(cr0).

This additional phase difference Δφ_(cr0) then compensate for the phase difference Δφ_(p) produced by the measured parameter. The sum of the two phase differences Δφ_(p) and Δφ_(cr) may then be kept at zero, which allows to make the interferometer operating with a better accuracy.

The measurement of the parameter to be measured is performed by using the signal required for the production of the feedback phase shift φ_(cr0).

The phase-cancellation method may be implemented thanks to a serrodyne modulation technique in which the feedback phase shift φ_(cr0) is a stair-step modulation, as shown in FIG. 1.

Each step has herein a width (or duration) Δτ_(g)=½ f_(p). Moreover, the height of each step is such that the phase-difference modulation Δφ_(cr0) introduced between the two counter-propagating waves compensate at each instant for the phase difference Δφ_(p) due to the measured parameter. As a function of the value, whether it is positive or negative, of this phase difference Δφ_(p), the feedback phase-shift modulation φ_(cr0) is either an ascending ramp (case of FIG. 1) or a descending ramp.

By combining the two above-exposed methods, i.e., on the one hand the biasing method, and on the other hand, the phase-cancellation method, it is then obtained a phase-shift modulation φ_(m0) that is the sum of the biasing phase-shift modulation φ_(b0) and of the feedback phase-shift modulation φ_(cr0). The result obtained is shown in FIG. 3, in which it can be observed that the phase-shift modulation φ_(m0) is an ascending pulse-wave modulation.

Moreover, it is known to make the feedback phase-shift modulation φ_(cr0) fall down. To limit the measurement errors, this falling down has for amplitude 2π as shown in FIG. 4. The falling down occurs when a step of the ramp is such that its level exceeds π, herein at the instant t=t_(R).

This falling down to 2π is made necessary by the fact that the value of the voltage applied to the phase modulator to produce the feedback phase shift φ_(cr0) cannot increase indefinitely.

Hence generated, the feedback phase-shift modulation φ_(cr0) has a maximum amplitude 401 lower than 2π.

The falling down to 2π of the feedback phase-shift modulation φ_(cr0) occurring at the instant t=t_(R), it follows that the phase-shift modulation φ_(m0) has two different profiles according to whether this falling down occurs during the passage of from a high level to a low level, or during the passage from a low level to a high level of the biasing phase-shift modulation φ_(b0).

Hence, in FIG. 6, it has be shown the case that will be called hereinafter the “wall” case, in which the phase-shift modulation φ_(m0) is the sum of the feedback phase-shift modulation φ_(cr0) of FIG. 4 and of the biasing phase-shift modulation φ_(b0) of FIG. 5, the latter passing from its high level +π/2a₀ to its low level −π/2a₀ at the instant t=t_(R).

It is then observed in FIG. 6 that the phase-shift modulation φ_(m0) falls down from a first level 61 to a second level 62, at the instant t=t_(R), the amplitude 63 between these two extreme levels being substantially equal to 2π+π/a₀.

Indeed, without the falling down of the ramp, the phase-shift modulation φ_(m0) would have passed, at the instant t=t_(R), from the first level 61 to the intermediate level 64 shown in dash line. Nevertheless, with the ramp falling down, the phase-shift modulation φ_(m0) sees the intermediate level 64 passing to the second level 62, the amplitude 65 between these two levels 62, 64 being equal to the amplitude of the ramp falling down, i.e 2π.

Likewise, in FIG. 8, it has been shown the case that will be called hereinafter the “stair” case, in which the phase-shift modulation φ_(m0) is the sum of the feedback phase-shift modulation φ_(cr0) of FIG. 4 and of the biasing phase-shift modulation φ_(b0) of FIG. 7, the latter passing from its low level −π/2a₀ to its high level +π/2a₀ at the instant t=t_(R).

It can be observed in FIG. 8 that, without the ramp falling down, the phase-shift modulation φ_(m0) should have passed, at the instant t=t_(R), from a first level 81 to a high level 84 shown in dash line. However, with the ramp falling down, the phase-shift modulation φ_(m0) sees the high level 84 passing to the second level 82, the amplitude 83 between these two levels 82, 84 being equal to the amplitude of the ramp falling down, i.e 2π.

Afterwards, during the transition of the biasing phase-shift modulation φ_(b0) from its high level to its lower level, the phase-shift modulation φ_(m0) passes from the second level 82 to a low level 85, located about π/a₀ lower.

Hence, the total amplitude 86 of the phase-shift modulation φ_(m0) is also substantially equal to 2π+π/a₀.

The “wall” and “stair” cases of FIGS. 6 and 8 relates to so-called “2-state” modulations (i.e. the two levels of the biasing modulation).

FIGS. 9 to 12 relates to so-called “4-state” modulations, such as those taught by the document EP0430747, for which the biasing phase-shift modulation φ_(b0) is such that, at each period of modulation, it is equal to:

-   -   φ₁ during the first quarter of period,     -   αφ₁ during the second quarter of period,     -   −φ₂ during the third quarter of period, and     -   −αφ₂ during the fourth quarter of period.

The values of α, φ₁ and φ₂ are chosen so that they satisfy the relation: cos (φ₁+φ₂)=cos [α(φ₁+φ₂)].

According to the proposition of the document EP0430747, two examples of biasing phase-shift modulation φ_(b0) have been shown in FIGS. 9 to 11, for which α=9/7 and φ₁=φ₂=7π/16.

The biasing phase-shift modulation φ_(b0) (4-state modulation) then takes sequentially four different values hence defining four modulation states:

-   -   two high states for which φ_(b0)=φ₁=7π/16 and φ_(b0)=αφ₁=9π/16,         and     -   two low states for which φ_(b0)=φ₂=−7π/16 and         φ_(b0)=−αφ₂=−9π/16.

The amplitude of this modulation between the extreme high and low levels is hence of 18π/16, i.e. an amplitude slightly higher than π.

Hence, using a biasing phase-shift modulation φ_(b0) as taught by the document EP0430747, a phase-shift modulation φ_(m0) as shown in FIGS. 10 and 12 is obtained.

FIG. 10 corresponds to a “stair” case, the biasing phase-shift modulation φ_(b0) associated with FIG. 9 passing from one of the two low levels to one of the two high levels at the instant t=t_(R) of the ramp falling down.

Likewise, FIG. 12 corresponds to a “wall” case, the biasing phase-shift modulation φ_(b0) associated with FIG. 11 operating a transition from one of the two high levels to one of the two low levels at the instant t=t_(R) of the ramp falling down.

Hence, in the two above-mentioned cases, the phase-shift modulation φ_(m0) proposed by the document EP0430747 has hence a total amplitude substantially equal to 2π+18π/16, i.e. a value higher than 3π.

To reach such a high amplitude, the voltage excursion (volts) on the phase modulator has to be high, so that the non-linearities of the modulation chain limit the accuracy of the parameter measurement.

SUMMARY OF THE INVENTION

So as to remedy the above-mentioned drawback, the object of the present invention is to propose a fibre-optic measurement device in which a parameter to be measured generates a phase difference between two counter-propagating waves in which the cumbersome effects of the non-linearities of the modulation chain are reduced.

For that purpose, the invention relates to a fibre-optic measurement device of the type in which a parameter to be measured generates a phase difference Δφ_(p) between two counter-propagating waves, including:

-   -   a light source,     -   a fiber-optic SAGNAC ring interferometer, preferably         single-mode, including a coil and a splitting element, in which         said two counter-propagating waves propagate, said ring         interferometer having a proper frequency f_(p),     -   an electromagnetic radiation detector, receiving the luminous         power exiting from said ring interferometer and delivering a         modulated electrical signal representative of the luminous         power, which is function of the total phase difference Δφ_(t)         between said two counter-propagating waves at the output of said         ring interferometer,     -   a modulation chain adapted to modulate said luminous power         exiting from said ring interferometer, said modulation chain         including at least one phase modulator placed in said ring         interferometer and adapted to generate at the output of said         modulation chain a phase-shift modulation φ_(m)(t), introducing         between said two counter-propagating waves a phase-difference         modulation Δφ_(m)(t) such that:         Δφ_(m)(t)=φ_(m)(t)−φ_(m)(t−Δτ_(g)), Δτ_(g)=1/(2 f_(p)) being the         transit time difference between said two counter-propagating         waves determined between said phase modulator and said splitting         element, and     -   signal processing means including:         -   an analog/digital converter digitizing said modulated             electrical signal received from the detector and             representative of said luminous power received by said             detector to deliver a digital electrical signal, and         -   a digital processing unit adapted to process said digital             electrical signal to deliver a signal function of said phase             difference Δφ_(p) and of said parameter to be measured,     -   biasing means adapted to generate a first biasing signal         producing at the output of the modulation chain a first, square         pulse-wave, biasing phase-shift modulation component φ_(b1)(t)         of amplitude π/a₁, a₁ being a non-zero real number, periodic at         a first biasing modulation frequency f_(b1) such that         f_(b1)=(2k₁+1)f_(p), k₁ being a natural number and f_(p) being         the proper frequency,     -   feedback means adapted to process said signal function of said         phase difference Δφ_(p) to generate a first feedback signal,         producing at the output of the modulation chain a first,         stair-step, feedback phase-shift modulation component         φ_(cr1)(t), each step having a duration Δτ_(g)/(2k₁+1), said         first feedback phase-shift modulation component φ_(cr1)(t)         introducing between said two counter-propagation waves a first         feedback phase-difference modulation component         Δφ_(cr1)(t)=φ_(cr1)(t)−φ_(cr1)(t−Δτ_(g)) that is function of         said phase difference Δφ_(p),     -   means for controlling said modulation chain, adapted to process         said first biasing signal and said first feedback signal to         deliver at least one first control signal at the input of said         modulation chain, producing at the output of the modulation         chain a first phase-shift modulation component φ_(m1)(t) that is         the phase sum of said first biasing phase-shift modulation         component φ_(b1)(t) and of said first feedback phase-shift         modulation component φ_(cr1)(t), such that         φ_(m1)(t)=φ_(b1)(t)+φ_(cr1)(t),         said fibre-optic measurement device being characterized in that         the means for controlling said modulation chain are arranged so         that said first phase-shift modulation component φ_(m1)(t)         operates a transition of twice the amplitude of the first         biasing phase-shift modulation component φ_(b1)(t), i.e. 2π/a₁,         when its level exceeds the amplitude of the first biasing         phase-shift modulation component φ_(b1)(t), i.e. π/a₁.

It will be understood herein that a transition of the first phase-shift modulation component φ_(m1)(t) corresponds to a change of its level, wherein such transition can be made:

-   -   either downwards when the first feedback phase-shift modulation         component φ_(cr1)(t) is an ascending stair-step modulation, such         that the first feedback phase-difference modulation component         Δφ_(cr1)(t) is positive when the phase difference Δφ_(p) due to         the parameter to be measured is negative,     -   or upwards when the first feedback phase-shift modulation         component φ_(cr1)(t) is an descending stair-step modulation,         such that the first feedback phase-difference modulation         component Δφ_(cr1)(t) is negative when the phase difference         Δφ_(p) due to the parameter to be measured is positive.

In the case of a downward transition of the first phase-shift modulation component φ_(m1)(t), it will hereinafter be talked about falling down of this modulation. In the case of an upward transition of the first phase-shift modulation component φ_(m1)(t), it will then be talked about rising up of this modulation.

Hence, said fibre-optic measurement device according to the invention allows to reduce the amplitude of the phase-shift modulation φ_(m)(t) thanks to the summing between the first biasing phase-shift modulation component φ_(b1)(t) and the feedback phase-shift modulation φ_(cr)(t) and to the transition operated by the modulation resulting from this sum.

Indeed, according to the invention, this amplitude is always lower than 2π/a₁, so that the excursion range used on the modulation chain is reduced. This hence limits the effects of the non-linearities of the modulation chain on the phase-shift modulation φ_(m), the latter having herein only one component φ_(m1).

Moreover, using a centred phase-shift modulation φ_(m1)(t), the defects appearing at the falling down or the rising up of the modulation due to the non-linearities of the modulation chain are eliminated. This allows in particular to control more easily the transfer function of the modulation chain.

Besides, other advantageous and non-limitative characteristics of the device according to the invention are as follows:

-   -   said first feedback phase-shift modulation component φ_(cr1)(t)         has stair steps of height −Δφ_(p)/(2k₁+1), such that said first         feedback phase-difference modulation component Δφ_(cr1)(t) is         such that Δφ_(cr1)(t)=−Δφ_(p), to compensate for said phase         difference Δφ_(p) due to the parameter to be measured;     -   said biasing means are adapted to generate a second biasing         signal producing at the output of the modulation chain a second         component of biasing phase-shift modulation φ_(b2)(t), said         second biasing phase-shift modulation component φ_(b2)(t) being:         -   a square pulse-wave modulation of amplitude π/a₂, a₂ being a             non-zero real number different from a₁,         -   periodic at a second biasing modulation frequency f_(b2)             such that f_(b2)=(2k₂+1)f_(p), k₂ being a natural number             such that (2k₁+1) and (2k₂+1) are multiples of each other,             and f_(p) being the proper frequency,         -   in quadrature relative to the first biasing phase-shift             modulation component φ_(b1)(t);     -   a₁=1;     -   a₂=1;     -   said fibre-optic measurement device also comprises means for         controlling the gain of said modulation chain allowing to keep         adjusted the transfer function of said modulation chain;     -   it is provided that:         -   a₁=1,         -   said first feedback phase-shift modulation component             φ_(cr1)(t) has stair steps of height             [a₂/(a₂−1)][−Δφ_(p)/(2k₁+1)], a₂ being a real number             strictly higher than a₁=1,         -   said biasing means are adapted to generate a second biasing             signal producing at the output of the modulation chain a             second biasing phase-shift modulation component φ_(b2)(t),             said second biasing phase-shift modulation component             φ_(b2)(t) being:             -   a square pulse-wave modulation of amplitude π/a₂,             -   periodic at a second biasing modulation frequency f_(b2)                 such that f_(b2)=f_(b1)=(2k₁+1)f_(p), f_(b1) being the                 first biasing modulation frequency and f_(p) being the                 proper frequency, and             -   in lagging quadrature relative to the first biasing                 phase-shift modulation component φ_(b1)(t),         -   said feedback means are adapted to generate a second             feedback signal, producing at the output of the modulation             chain a second feedback phase-shift modulation component             φ_(cr2)(t), said second feedback phase-shift modulation             component φ_(cr2)(t) being:             -   a stair-step modulation, each step having a duration                 Δτ_(g)/(2k₁+1) and a height [1/(a₂−1)][−Δφ_(p)/(2k₁+1)],             -   in lagging quadrature relative to the first feedback                 phase-shift modulation component φ_(cr1)(t), and             -   said second feedback phase-shift modulation component                 φ_(cr2)(t) introducing a second feedback                 phase-difference modulation component                 Δφ_(cr2)(t)=φ_(cr2)(t)−φ_(cr2)(t−Δτ_(g)) between said                 two counter-propagating waves, such that the difference                 between the first feedback phase-difference modulation                 component Δφ_(cr1)(t) and the second feedback                 phase-difference modulation component Δφ_(cr2)(t)                 compensates for the phase difference Δφ_(p), i.e.                 Δφ_(cr1)(t)−Δφ_(cr2)(t)=−Δφ_(p),         -   said means for controlling said modulation chain are adapted             to process said second biasing signal and said second             feedback signal to deliver at least one second control             signal at the input of said modulation chain, producing at             the output of the modulation chain a second phase-shift             modulation component φ_(m2)(t) that is the sum of said             second biasing phase-shift modulation component φ_(b2)(t)             and said second feedback phase-shift modulation component             φ_(cr2)(t), so that φ_(m2)(t)=φ_(b2)(t)+φ_(cr2)(t), and         -   the control means are arranged so that said second             phase-shift modulation component φ_(m2)(t) operates a             transition of twice the amplitude of the second biasing             phase-shift modulation component φ_(b2)(t), i.e. 2π/a₂, when             its level exceeds the amplitude of the second biasing             phase-shift modulation component φ_(b2)(t), i.e. π/a₂, the             phase-shift modulation φ_(m)(t) being equal to the             difference between the first phase-shift modulation             component φ_(m1)(t) and the second phase-shift modulation             component φ_(m2)(t), so that φ_(m)(t)=φ_(m1)(t)−φ_(m2)(t),     -   k₂=0, and     -   k₁=0.

The measurement device according to the invention is particularly well adapted to the realization of a gyrometer. In this case, the parameter to be measured is a component of the rotational speed of the ring interferometer.

Hence, the invention also relates to a gyrometer, characterized in that it is compliant with the fiber-optical measurement device according to the invention, the parameter to be measured being a component of the rotational speed of the ring interferometer.

This gyrometer advantageously enters into the making of navigation or inertial-stabilization systems.

Hence, the invention also proposes a navigation or inertial-stabilization system including at least one gyrometer according to the invention.

BRIEF DESCRIPTION OF THE DRAWING FIGURES

Embodiments of the invention will be described in detail with reference to the drawings in which:

FIG. 1 shows an ascending stair-step feedback phase-shift modulation φ_(cr0) according to the prior art;

FIG. 2 shows a pulse-wave biasing phase-shift modulation φ_(b0) according to the prior art;

FIG. 3 shows a phase-shift modulation φ_(m0) according to the prior art, which is the sum of the feedback phase-shift modulation φ_(cr0) of FIG. 1 and of the biasing phase-shift modulation φ_(b0) of FIG. 2;

FIG. 4 shows an ascending stair-step feedback phase-shift modulation φ_(cr0) according to the prior art, which falls down by 2π at the instant t=t_(R);

FIG. 5 shows a pulse-wave biasing phase-shift modulation φ_(b0) according to the prior art, which passes from a high level to a low level at the instant t=t_(R);

FIG. 6 shows a phase-shift modulation φ_(m0) according to the prior-art, which is the sum of the feedback phase-shift modulation φ_(cr0) of FIG. 4 and of the biasing phase-shift modulation φ_(b0) of FIG. 5;

FIG. 7 shows a pulse-wave biasing phase-shift modulation φ_(b0) according to the prior art, which passes from a low level to a high level at the instant t=t_(R);

FIG. 8 shows a phase-shift modulation φ_(m0) according to the prior art, which is the sum of the feedback phase-shift modulation φ_(cr0) of FIG. 4 and of the biasing phase-shift modulation φ_(b0) of FIG. 7;

FIG. 9 shows a so-called “4-state” biasing phase-shift modulation φ_(b0) according to the prior art, which passes from a low level to a high level at the instant t=t_(R);

FIG. 10 shows a phase-shift modulation φ_(m0) according to the prior art, which is the sum of the feedback phase-shift modulation φ_(cr0) of FIG. 4 and of the biasing phase-shift modulation φ_(b0) of FIG. 9;

FIG. 11 shows a so-called “4-state” biasing phase-shift modulation φ_(b0) according to the prior art, which passes from a high level to a low level at the instant t=t_(R);

FIG. 12 shows a phase-shift modulation φ_(m0) according to the prior art, which is the sum of the feedback phase-shift modulation φ_(cr0) of FIG. 4 and of the biasing phase-shift modulation φ_(b0) of FIG. 11;

FIG. 13 shows a schematic view of the measurement device according to the prior art;

FIG. 14 shows a functional diagram representing the different means implemented in the measurement device according to the invention;

FIG. 15 shows a first biasing phase-shift modulation component φ_(b1)(t) as a function of time t;

FIG. 16 shows a first feedback phase-shift modulation component φ_(cr1)(t) as a function of time t, in the form of an ascending stair-step ramp;

FIG. 17 shows a first phase-shift modulation component φ_(m1)(t) as a function of time t, which is the sum of the first biasing phase-shift modulation component φ_(b1)(t) of FIG. 15 and of the first feedback phase-shift modulation component φ_(cr1)(t) of FIG. 16;

FIG. 18 shows a first feedback phase-shift modulation component φ_(cr1)(t) as a function of time t, in the form of a descending stair-step ramp;

FIG. 19 shows a first phase-shift modulation component φ_(m1)(t) as a function of time t, which is the sum of the first biasing phase-shift modulation component φ_(b1)(t) of FIG. 15 and of the first feedback phase-shift modulation component φ_(cr1)(t) of FIG. 18;

FIG. 20 shows the first phase-difference modulation component Δφ_(m1)(t) corresponding to the first phase-shift modulation component φ_(m1)(t) of FIG. 17;

FIG. 21 shows the first phase-difference modulation component Δφ_(m1)(t) corresponding to the first phase-shift modulation component φ_(m1)(t) of FIG. 19;

FIG. 22 shows the total phase difference Δφ_(t)(t) in a first embodiment of the invention, the luminous power received by the detector at the output of the interferometer and the corresponding modulated electrical signal;

FIG. 23 shows a functional diagram showing the different means implemented in the measurement device according to the invention and comprising means for controlling the transfer function of the modulation chain;

FIG. 24 shows a first phase-shift modulation component φ_(m1)(t) in a second embodiment of the invention;

FIG. 25 shows a second biasing phase-shift modulation component φ_(b2)(t) of levels +π/8 and −π/8, in a second embodiment of the invention;

FIG. 26 shows the phase-shift modulation φ_(m)(t) in the second embodiment, resulting from the summing of the first phase-shift modulation component φ_(m1)(t) of FIG. 24 and of the second biasing phase-shift modulation component φ_(b2)(t) of FIG. 25;

FIG. 27 shows the phase-difference modulation Δφ_(m)(t) corresponding to the phase-shift modulation φ_(m)(t) of FIG. 26;

FIG. 28 shows the total phase difference Δφ_(t)(t) in the second embodiment of the invention, the luminous power received by the detector at the output of the interferometer and the corresponding modulated electrical signal when the transfer function of the modulation chain is correctly adjusted;

FIG. 29 shows the total phase difference Δφ_(t)(t) in the second embodiment of the invention, the luminous power received by the detector at the output of the interferometer and the corresponding modulated electrical signal when the first feedback phase-difference modulation component Δφ_(cr1)(t) does not compensate exactly for the phase difference Δφ_(p) due to the parameter to be measured and when the transfer function of the modulation chain is correctly adjusted;

FIG. 30 shows the total phase difference Δφ_(t)(t) in the second embodiment of the invention, the luminous power received by the detector at the output of the interferometer and the corresponding modulated electrical signal when the transfer function of the modulation chain is incorrectly adjusted;

FIG. 31 shows a first phase-shift modulation component φ_(m1)(t) in a third embodiment of the invention;

FIG. 32 shows a second biasing phase-shift modulation component φ_(b2)(t) of levels +π/2 and −π/2, in the third embodiment of the invention;

FIG. 33 shows the phase-shift modulation φ_(m)(t) in the third embodiment, resulting from the summing of the first phase-shift modulation component φ_(m1)(t) of FIG. 31 and of the second biasing phase-shift modulation component φ_(b2)(t) of FIG. 32;

FIG. 34 shows the phase-difference modulation Δφ_(m)(t) corresponding to the phase-shift modulation φ_(m)(t) of FIG. 33;

FIG. 35 shows the total phase difference Δφ_(t)(t) in the third embodiment of the invention, the luminous power received by the detector at the output of the interferometer and the corresponding modulated electrical signal when the transfer function of the modulation chain is correctly adjusted;

FIG. 36 shows a first phase-shift modulation component φ_(m1)(t) in a fourth embodiment of the invention;

FIG. 37 shows a second phase-shift modulation component φ_(m2)(t) in a fourth embodiment of the invention;

FIG. 38 shows the phase-shift modulation φ_(m)(t) in the fourth embodiment, resulting from the difference between the first phase-shift modulation component φ_(m1)(t) of FIG. 36 and the second phase-shift modulation component φ_(m2)(t) of FIG. 37;

FIG. 39 shows the phase-difference modulation Δφ_(m)(t) corresponding to the phase-shift modulation φ_(m)(t) of FIG. 38;

FIG. 40 shows the total phase difference Δφ_(t)(t) in the fourth embodiment of the invention, the luminous power received by the detector at the output of the interferometer and the corresponding modulated electrical signal when the transfer function of the modulation chain is correctly adjusted.

DETAILED DESCRIPTION OF THE INVENTION

FIG. 13 shows a fibre-optic measurement device 10 according to the prior art, of the type in which a parameter to be measured generates a phase difference Δφ_(p) between two waves.

The fibre-optic measurement device 10 first includes a light source 11 herein comprising a laser diode.

As a variant, the light source may comprise for example a super-luminescent diode or a doped-fibre light source of the ASE (“Amplified Spontaneous Emission”) type.

The device 10 also comprises a first splitting element 12. This first splitting element 12 is herein a semi-reflective plate having a transmittance of 50% and a reflectance of 50%.

As a variant, the splitting element may be, for example, a −3-decibel 2×2 coupler or an optical circulator.

The luminous wave emitted by the light source 11 is hence transmitted in part by the first splitting element 12 towards an optical filter 13 at the output of which the luminous wave has been filtered. The optical filter 13 preferably includes a polarizer and a spatial filter. This spatial filter is herein a single-mode optical fiber, preferably of the polarization-maintaining type.

The device 10 also includes a SAGNAC ring interferometer 20 comprising a fiber-optic coil 21 wound around itself. It is herein an optical fiber, preferably of the single-mode and polarization-maintaining type.

This SAGNAC ring interferometer 20 also comprises a second splitting element 23 allowing to split the wave exiting from the optical filter 13 into two counter-propagating waves 24, 25 on the two arms of the ring interferometer 20, these two arms defining two optical paths 24A and 25A. The second splitting element 23 is herein a semi-reflective plate having a transmittance of 50% and a reflectance of 50%.

The second splitting element 23 also allows to recombine the two counter-propagating waves 24, 25 at the output of the ring interferometer 20.

As a variant, the second splitting element may be, for example, a −3-decibel 2×2 coupler or a “Y”-junction in integrated optics.

The two counter-propagating waves 24, 25 then pass through the optical filter 13 and are reflected by the first splitting element 12 towards an electromagnetic radiation detector 14.

This detector 14 is a semi-conductor photodiode.

The detector 14 is sensitive to the luminous power P received, which is herein function of the interference state between the two counter-propagating waves 24, 25 during their recombination at the output of the SAGNAC ring interferometer 20. It hence delivers an electrical signal that is representative of the total phase difference Δφ_(t) between the two counter-propagating waves 24, 25.

It is known that, for a SAGNAC ring interferometer 20, the luminous power P(Δφ_(t)) received by the detector as a function of the total phase difference Δφ_(t) is a cosine function of this total phase difference Δφ_(t), i.e. the following relation is satisfied: P(Δφ_(t))=P0[1+cos(Δφ_(t))].

It will be seen in the following of the description that this electrical signal is a modulated electrical signal.

The device 10 also includes a modulation chain 30 comprising a digital/analog converter 31, an amplifier 32 and a phase modulator 33.

The digital/analog converter 31 processes a digital control signal delivered by the electronic means 100, the decomposition of this signal being described in detail hereinafter. The digital/analog converter 31 delivers as an output an analog control signal.

The amplifier 32 then processes this analog control signal to deliver a modulation control voltage V_(m)(t) to the phase modulator 33.

The phase modulator 33 is placed in the ring interferometer 20 and is thus also a part thereof. It herein advantageously comprises a pair of elementary phase modulators 33A, 33B mounted in “push-pull” configuration, placed respectively at each of the ends of the arms of the SAGNAC ring interferometer 20.

It is known that the “push-pull” mounting allows to eliminate the response of the phase modulator 33 and the non-linearities of even order (2^(nd) order, 4^(th) order, etc. . . . ). Hence, the modulation chain 30 has an odd non-linear response with for main components the component of 1^(st) order (linear component) and the component of 3^(rd) order.

The elementary phase modulator 33A, 33B are herein of the so-called “Pockels effect”, electro-optical type, in proton-exchange lithium-niobate integrated optics.

The phase modulator 33 allows, when the time-dependant control modulation voltage V_(m)(t) is applied at the input thereof, to generate a proportional phase-shift modulation φ_(m)(t), and thus with the same time dependency, in a luminous wave passing through it at the given instant t in one direction or another.

In the case of the SAGNAC ring interferometer 20 shown in FIG. 13, the transit-time difference of the counter-propagating waves 24, 25 along the two optical paths 24A, 25A between the phase modulator 33 and the second splitting element 23 is denoted Δτ_(g).

Hence, the phase-shift modulation φ_(m)(t) generated by the phase modulator 33 controlled by the modulation control voltage V_(m)(t) introduces between the two counter-propagating waves 24, 25, a phase-difference modulation Δφ_(m)(t) such that: Δφ_(m)(t)=φ_(m)(t)−φ_(m)(t−Δτ_(g)).

The transit-time difference Δτ_(g) also defines a proper frequency f_(p) of the SAGNAC ring interferometer 20 by the relation: f_(p)=1/(2Δτ_(g)).

This proper frequency f_(p) thus depends on the length of the coil 21 in the SAGNAC ring interferometer 20. With the fiber-optic coil 21 used herein, a coil having a length of 1 kilometer, the proper frequency f_(p) of the SAGNAC ring interferometer 20 is of about 100 kilohertz (kHz), corresponding to a transit-time difference Δτ_(g) of 5 microseconds (μs).

The luminous power P(Δφ_(t)) received by the detector 14 is also modulated and the electrical signal delivered by the detector 14 will thus be a modulated electrical signal, examples of which will be given hereinafter.

This modulated electrical signal is transmitted to electronic means 100 that process it to deliver a signal function of the phase difference Δφ_(p) and of the parameter to be measured.

For that purpose, the electronic means 100 comprise signal processing means 110, as shown in FIG. 14. These signal processing means 110 include an analog/digital converter 111 digitizing the modulated electrical signal provided by the detector 14 to deliver a digital electrical signal.

This digitization operation is performed at a synchronization frequency fixed by the clock 101. The synchronization frequency of the clock 101 is preferably a multiple of the proper frequency f_(p) of the SAGNAC ring interferometer 20.

The signal processing means 110 also comprise a digital processing unit 112 configured to process the digital electrical signal provided at the output of the analog/digital converter 111. The digital processing unit 112 also includes a digital demodulator, a control-loop digital filter fed with a first demodulated digital signal exiting from the digital demodulator and a register.

The digital processing unit 112 delivers a signal function of the phase difference Δφ_(p) and of the parameter to be measured for any desired external use.

The electronic means 100 also control in return the modulation chain 30.

For that purpose, the electronic means 100 include, on the one hand, biasing means 130 and, on the other hand, feedback means 120.

On one side, the biasing means 130 generate a first biasing signal producing at the output of the modulation chain a first biasing phase-shift modulation component φ_(b1)(t) as shown in FIG. 15.

This first biasing phase-shift modulation component φ_(b1)(t) is a pulse-wave modulation having herein a high level of value π/2a₁ (a₁ being a non-zero real number) and a low level of value −π/2a₁.

This modulation is hence:

-   -   square: the duration of the high level is herein equal to the         duration of the low level, and     -   of amplitude π/a₁, the amplitude being defined as the distance         between the high level (π/2a₁) and the low level (−π/2a₁) of the         modulation, i.e. π/2a₁−(−π/2a₁)=2(π/2a₁)=π/a₁.

As illustrated in FIG. 15, it is advantageous that the first phase-shift modulation component φ_(m1)(t) is centred about zero. Indeed, this allows to reduce the effects of the non-linearities of the modulation chain 30, in particular thanks to the “push-pull” mounting of the phase modulator 33.

Nevertheless, according to the invention, an equivalent result would be obtained with a non-centred modulation.

Furthermore, the first biasing phase-shift modulation component φ_(b1)(t) is a periodic modulation at a first biasing modulation frequency f_(b1), which is herein such that f_(b1)=f_(p), f_(p) being the proper frequency of the SAGNAC ring interferometer 20. The period of the first biasing phase-shift modulation component φ_(b1)(t) is thus equal to 2Δτ_(g) and the duration of each of the high and low levels is equal to Δτ_(g).

Generally, the first biasing modulation frequency f_(b1) may be such that f_(b1)=(2k₁+1)f_(p), k₁ being a natural number and f_(p) being the proper frequency.

The biasing means 130 are configured so as to generate a first biasing signal at precise instants, synchronized by the frequency of the clock 101.

The biasing means 130 allows to displace the operating point of the measurement device 10 so as to use it with the best possible sensitivity.

On the other side, the feedback means 120 process the signal function of the phase difference Δφ_(p) to generate a first feedback signal, producing at the output of the modulation chain a first feedback phase-shift modulation component φ_(cr1)(t) as shown in FIG. 16.

This first feedback phase-shift modulation component φ_(cr1)(t) is a stair-step modulation, each stair step having herein a duration Δτ_(g).

Generally, and when the first biasing modulation frequency f_(b1) is such that f_(b1)=(2k₁+1)f_(p), the first feedback phase-shift modulation component φ_(cr1)(t) has stair steps of duration Δτ_(g)/(2k₁+1).

The first feedback phase-shift modulation component φ_(cr1)(t) is in phase with the first biasing phase-shift modulation component φ_(b1)(t), i.e. the first feedback phase-shift modulation component φ_(cr1)(t) passes from one step to another upon the passage of the first biasing phase-shift modulation component φ_(b1)(t) from one level to another.

Besides, as illustrated in FIG. 16, the first feedback phase-shift modulation component φ_(cr1)(t) has stair steps of height φ_(s) function of said phase difference Δφ_(p). The level of each step being herein higher than the previous one, it is hence referred to an ascending ramp for the first feedback phase-shift modulation component φ_(cr1)(t).

FIG. 18 shows an example of the first feedback phase-shift modulation component φ_(cr1)(t), which is a descending ramp, where the level of each step is lower than the previous one. It will be seen in the following of the description in which case the ramp is ascending and in which case it is descending.

The first feedback phase-shift modulation component φ_(cr1)(t) introduces, between the two counter-propagation waves 24, 25, a first feedback phase-difference modulation component Δφ_(cr1)(t)=φ_(cr1)(t)−φ_(cr1)(t−Δτ_(g))=φ_(s) that is a function of the phase difference Δφ_(p).

The feedback means 120 herein include an accumulator.

The electronic means 100 further include control means 140 for controlling the modulation chain 30, which process the first biasing signal and the first feedback signal to deliver at least one first control signal at the input of the modulation chain 30.

This first control signal produces at the output of the modulation chain 30 a first phase-shift modulation component φ_(m1)(t), which is the phase sum of the first biasing phase-shift modulation component φ_(b1)(t) and the first feedback phase-shift modulation component φ_(cr1)(t), such that φ_(m1)(t) satisfies the relation: φ_(m1)(t)=φ_(b1)(t)+φ_(cr1)(t).

The control means 140 have two inputs and one output. At the input, the control means 140 receive on the one hand the first feedback signal and on the other hand the first biasing signal. These signals are then processed by the control means 140. At the output, the control means 140 deliver the first control signal, which is then transmitted to the modulation chain 30.

Hence controlled, the modulation chain 30 generates a first phase-shift modulation component φ_(m1)(t) via the phase modulator 33. A first phase-difference modulation Δφ_(m1)(t) is then introduced between the two counter-propagating waves 24, 25 propagating in the SAGNAC ring interferometer 20.

The different particular embodiments of the invention allowing to limit the effects of the non-linearities of the modulation chain 30 on the measurement of the phase difference Δφ_(p) and of the parameter to be measured will now be described.

1st Embodiment

In this first particular embodiment of the invention, the first biasing modulation component φ_(b1)(t) 1500 is that shown in FIG. 15, and the first feedback modulation component φ_(cr1)(t) 1600 is that shown in FIG. 16.

According to the invention, the control means 140 for controlling the modulation chain 30 are arranged in such a manner that the first phase-shift modulation component φ_(m1)(t) operates a transition of twice the amplitude of the first biasing phase-shift modulation component φ_(b1)(t), i.e. 2π/a₁, when its level exceeds the amplitude of the first biasing phase-shift modulation component φ_(b1)(t), i.e. π/a₁.

This may be understood at the light of FIG. 17, on which has been shown the first phase-shift modulation component φ_(m1)(t) 1700, which as the form of an ascending pulse-wave modulation, due to the ascending ramp of FIG. 16.

It can be observed in FIG. 17 that, at the instant t=t_(R), the first phase-shift modulation component φ_(m1)(t) had to pass from a low level before falling down 1701 to a high level 1702 shown in dash line.

However, as this high level 1702 is such that it slightly exceeds the value π/a₁, i.e. the value of the amplitude of the first biasing phase-shift modulation component φ_(b1)(t) 1500, the control means 140 make the phase-shift modulation component φ_(m1)(t) 1700 fall down to bring the high level 1702 to the low level after falling down 1703. The amplitude 1704 of this falling down is hence herein equal to 2π/a₁, i.e. twice the amplitude of the first biasing phase-shift modulation component φ_(b1)(t) 1500.

So formed, the first phase-shift modulation component φ_(m1)(t) 1700 has a maximal amplitude 1705 equal to 2π/a₁. The amplitude is hence lowered and the excursion on the modulation chain 30 is reduced, limiting the effects of the non-linearities of this modulation chain 30.

According to an advantageous characteristic of this first embodiment of the invention, the first feedback phase-shift modulation component φ_(cr1)(t) 1600 of FIG. 16 has stair steps of height φ_(s) such that: φ_(s)=−Δφ_(p), in such a manner that the feedback phase-difference modulation Δφ_(cr1)(t) is equal to −Δφ_(p), to compensate for the phase difference Δφ_(p) due to the parameter to be measured.

This allows in particular to make the device 10 operate in closed loop so as to reach a good linearity and stability of the measurement of the parameter generating the phase difference Δφ_(p).

In the case where the phase difference Δφ_(p) due to the parameter to be measured is positive, the height φ_(s) of the stair steps of the first feedback phase-shift modulation component φ_(cr1)(t) 1800 is negative, which means that this first component is a descending ramp, as shown in FIG. 18.

The first phase-shift modulation component φ_(m1)(t) 1900 then takes the form of a descending pulse-wave modulation (see FIG. 19).

It can be observed in FIG. 19 that, at the instant t=t_(R), the first phase-shift modulation component φ_(m1)(t) 1900 had to pass from a high level before falling down 1901 to a low level 1902 shown in dash line.

However, as this low level 1902 is such that it slightly exceeds, in absolute value, the value π/a₁, i.e. the value of the amplitude of the first biasing phase-shift modulation component φ_(b1)(t) 1500, the control means 140 make the first phase-shift modulation component φ_(m1)(t) 1900 rise up, to bring the low level 1902 to the high level after rising up 1903. The amplitude 1904 of this rising up is hence equal to 2π/a₁, i.e. twice the amplitude of the first biasing phase-shift modulation component φ_(b1)(t) 1500.

So formed, the first phase-shift modulation component φ_(m1)(t) still has a maximum amplitude 1905 equal to 2π/a₁.

By comparing the cases of FIGS. 17 and 19, corresponding, respectively, to the case of an ascending ramp and to the case of a descending ramp, it is understood that the first phase-shift modulation component φ_(m1)(t) is caused to fall down or to rise up when the value of the level it should have reached without falling down (or rising up) is higher, in absolute value, than twice the amplitude of the first biasing phase-shift modulation component φ_(b1)(t).

Moreover, it will be noted that, in this first embodiment of the invention, the falling down (or the rising up) of the first phase-shift modulation component φ_(m1)(t) is such that the latter has a maximum amplitude, between its highest level and its lowest level, lower than or equal to twice the amplitude of the first biasing phase-shift modulation component φ_(b1)(t), i.e. 2π/a₁.

Hence, the amplitude of the phase-shift modulation is reduced with respect to the case in which a falling down (or rising up) by 2π is made on the first feedback phase-shift modulation component φ_(cr1)(t), independently of its sum with the first biasing phase-shift modulation component φ_(b1)(t). Indeed, in this case, the maximal amplitude would be of about 2π+π/a₁.

It has be shown in FIGS. 20 and 21, respectively, the first phase-difference modulation components Δφ_(m1)(t) introduced between the counter-propagating waves 24, 25 and resulting from the generation of the first phase-shift modulation components φ_(m1)(t) of FIGS. 17 and 19, respectively, by the modulation chain 30 controlled by the control means 140.

In the case of an ascending ramp (i.e. φ_(s)>0, case of FIG. 20), the first phase-difference modulation component Δφ_(m1)(t) 2000 is a pulse-wave modulation, having a high level of value +π/a₁+φ_(s) and a low level of value −π/a₁+φ_(s), these extreme levels being hence symmetrical with respect to the level line of ordinate φ_(s).

The first phase-difference modulation component Δφ_(m1)(t) 2000 has a total amplitude equal to 2π/a₁.

Moreover, it can be observed in FIG. 20 that the first phase-difference modulation component Δφ_(m1)(t) 2000 is alternately at its high level and at its low level, until the instant t=t_(R) of the falling down of the first phase-shift modulation component φ_(m1)(t) 1700 (see FIG. 17), where it remains at the same low level 2001, instead of getting to the high level 2002. Next, the first phase-difference modulation component Δφ_(m1)(t) 2000 resumes its alternations between its high level and its low level, and this until the next falling down.

Likewise, in the case of a descending ramp (i.e. φ_(s)<0, case of FIG. 21), the first phase-difference modulation component Δφ_(m1)(t) 2100 is a pulse-wave modulation, having a high level of value +π/a₁+φ_(s) and a low level of value −π/a₁+φ_(s), these extreme levels being thus symmetrical with respect to the level line of ordinate φ_(s) (herein φ_(s)<0).

The first phase-difference modulation component has a total amplitude Δφ_(m1)(t) 2100 equal to 2π/a₁.

Moreover, it can be observed in FIG. 21 that the phase-shift modulation component Δφ_(m1)(t) 2100 is alternately at its high level and at its low level, until the instant t=t_(R) of the rising up of the phase-shift modulation component φ_(m1)(t) 1900 (see FIG. 19), where it remains at the same high level 2101, instead of getting to the low level 2102. Next, the first phase-difference modulation component Δφ_(m1)(t) 2100 resumes its alternations between its high level and its low level, until the next rising up.

FIG. 22 is an example of the first embodiment of the invention for which a₁=4/3. Hence, in FIG. 22, it has been shown the total phase difference Δφ_(t) 2200 between the two counter-propagating waves 24, 25 propagating in the SAGNAC ring interferometer 20. The total phase difference Δφ_(t) is herein the sum of the phase difference Δφ_(p) due to the parameter to be measured and of the first phase-difference modulation component Δφ_(m1): Δφ_(t)=Δφ_(p)+Δφ_(m1).

For this example, the first phase-shift modulation component φ_(m1)(t) is formed based on:

-   -   a first biasing phase-shift modulation component φ_(b1)(t) of         levels +3π/8 (=π/2a₁) and −3π/8 (=−π/2a₁), and     -   a first feedback phase-shift modulation component φ_(cr1)(t)         such that the step value φ_(s) compensates for the phase         difference Δφ_(p) of the parameter to be measured, so that         φ_(s)=−Δφ_(p).

Hence, the first phase-difference modulation component Δφ_(m1)(t) introduced between the two counter-propagative waves 24, 25 from the generation of the first phase-shift modulation component φ_(m1)(t) by the modulation chain 30 is similar to that shown in FIG. 22. This is a pulse-wave modulation, of symmetrical extreme levels, of values +3π/4 (high level 2201) and −3π/4 (low level 2202), its total amplitude 2203 being equal to 3π/2.

As explained hereinabove for the first phase-difference modulation component Δφ_(m1)(t), the total phase difference Δφ_(t) is alternately at its high level and at its low level, until the instant t=t_(R) of the falling down, where it remains at the same level 2204, instead of getting to the high level 2205 shown in dash line.

It has also been shown in FIG. 22 the response of the ring interferometer 20, i.e. the luminous power received P(Δφ_(t)) 2206 by the detector at the output of the interferometer. This received luminous power is cosine waveform: P(Δφ_(t))=P₀[1+cos(Δφ_(t))], and has a maximum equal to 2P₀ when the total phase difference Δφ_(t) is null (Δφ_(t)=0).

The total phase difference Δφ_(t) being modulated as described above, the luminous power P(Δφ_(t)) 2206 received by the detector 14 is modulated according to two distinct modulation states:

-   -   a state E1 for which Δφ_(t)=Δφ₁=3π/4, and     -   a state E2 for which Δφ_(t)=Δφ₂=−3π/4.

As can be seen in FIG. 22, the luminous power P(Δφ_(t)) 2206 received by the detector 14 is the same in the two modulation states E1 and E2. Indeed, the received luminous power P(Δφ_(t)) 2206 being a cosine function of the total phase difference Δφ_(t), the following relation is satisfied: P(Δφ₁)=P(Δφ₂).

The detector 14 then delivers a modulated electrical signal S(t) 2207 such as shown in FIG. 22. This modulated electrical signal S(t) 2207 takes sequentially two values S1 and S2 associated with the two modulation states E1 and E2, respectively, of the modulated total phase difference Δφ_(t).

It will also been observed in FIG. 22 that the modulated electrical signal S(t) 2207 exhibits peaks 2208 corresponding to the transitions from the modulation state E1 to the modulation state E2 (and vice versa), when the received luminous power P(Δφ_(t)) 2206 passes by a maximum at the value Δφ_(t)=0, this maximum having the value 2P₀.

These peaks 2208 are cumbersome insofar as they introduce unwanted defects in the modulated electrical signal S(t) 2207.

The modulated electrical signal S(t) 2207 is then digitized by the analog/digital converter 111, which delivers and transmits a digital electrical signal to the digital processing unit 112.

It is important to note herein that the falling down of the first phase-shift modulation component φ_(m1)(t) at the instant t=t_(R) creates no defect in the modulated electrical signal S(t) 2207 insofar as the total phase difference Δφ_(t) does not change during this falling down. Hence, the falling down does not disturb the measurement.

2^(nd), 3^(rd) and 4^(th) Embodiments of the Invention

FIGS. 23 to 40 relates to three particular embodiments of the invention in the total phase difference Δφ_(t) between the two counter-propagating waves 24, 25 is no longer modulated according to two modulation states but according to four modulation states. It will be seen in particular how these particular embodiments allow to control the modulation chain 30.

Indeed, advantageously, in these second, third and fourth embodiments of the invention, it is known that the electronic means 100 of the fibre-optic measurement device 10 include gain-control means 150 such as shown in FIG. 23. These gain-control means 150 keep adjusted the transfer function of the modulation chain 30, this transfer function electronically characterizing the modulation chain 30 between its input and its output.

This transfer function characterizes the response of the modulation chain 30: it corresponds to the ratio between the value (in radians) of the phase shift effectively generated by the modulation chain 30 via the phase modulator 33 and the value (with no unit) of the digital control signal transmitted to the modulation chain 30.

The gain control means 150 comprise another digital processing unit (not shown) using the digital electrical signal delivered by the analog/digital converter 111 so as to provide a signal function of the transfer function of the modulation chain 30.

This later signal is filtered by a digital control-loop integrator filter which feeds another digital/analog converter controlling the variable gain G of the amplifier 32 or the reference analog voltage of the digital/analog converter 31.

Hence, the transfer function of the modulation chain 30 is kept correctly adjusted, as well as the modulation control voltage delivered by the amplifier 32 to the phase modulation 33.

It is meant by this that a given value of the digital control signal at the input of the modulation chain 30 will always give the same value (in radians) of phase-shift modulation φ_(m) generated by the phase modulator 33, and hence the same value (in radians) of phase-difference modulation Δφ_(m) introduced between the two counter-propagating waves 24, 25 in the SAGNAC ring interferometer 20.

It will be understood at the light of the following description how operate the control means 150 and how they allow to keep correctly adjusted the transfer function of the modulation chain 30.

2^(nd) Embodiment

It will now be detailed, in FIGS. 24 to 30, a second embodiment of the invention, in which:

-   -   a₁=1 and k₁=0, i.e. the first biasing phase-shift modulation         component φ_(b1)(t) is a square pulse-wave modulation of         amplitude π between a high level +π/2 and a low level −π/2 and         periodic at a first biasing modulation frequency f_(b1) equal to         the proper frequency f_(p) of the SAGNAC ring interferometer 20,         and     -   Δφ_(p)=−π/20, so that the first feedback phase-shift modulation         component φ_(cr1)(t) is an ascending stair-step modulation of         height φ_(s)=−Δφ_(p)=π/20 compensating for the phase difference         Δφ_(p) due to the parameter to be measured.

Hence, according to the invention, the first phase-shift modulation component φ_(m1)(t) is such as shown in FIG. 24. It has an ascending pulse-wave modulation shape, which falls down by 2π at the instant t=t_(R), and has a maximum amplitude lower than 2π.

Furthermore, in this second embodiment of the invention, the biasing means 120 generate a second biasing signal producing at the output of the modulation chain 30 a second biasing phase-shift modulation component φ_(b2)(t) 2500, this second biasing phase-shift modulation component φ_(b2)(t) 2500 being (cf. FIG. 25):

-   -   a square pulse-wave modulation of amplitude π/a₂=π/4, with         herein a₂=4≠a₁=1, between a high level +π/8 and a low level         −π/8,     -   periodic at a second biasing modulation frequency f_(b2) such         that f_(b2)=(2k₂+1)f_(p)=f_(p), with k₂=k₁=0 so that (2k₁+1)=1         and (2k₂+1)=1 are multiple of each other,     -   in quadrature relative to the first biasing phase-shift         modulation component φ_(b1)(t).

It will be defined herein that the first biasing phase-shift modulation component φ_(b1)(t) and the second biasing phase-shift modulation component φ_(b2)(t) 2500 are in quadrature when a transition of the first biasing phase-shift modulation component φ_(b1)(t) from an extreme level to another occurs at equal distance from two successive zeros of the second biasing phase-shift modulation component φ_(b2)(t) 2500.

It has been shown in FIG. 26 the phase-shift modulation φ_(m)(t) 2600 resulting from the sum of the first phase-shift modulation component φ_(m1)(t) 2400 and of the second biasing phase-shift modulation component φ_(b2)(t) 2500.

It can be observed in FIG. 26 that, taking into account that the first feedback phase-shift modulation component φ_(cr1)(t) is herein an ascending modulation, the first phase-shift modulation component φ_(m1)(t) 2400 falls down by 2π according to the above-described rule, at the falling down instant t=t_(R). Likewise, the resulting phase-shift modulation φ_(m)(t) 2600 also falls down at the same instant t=t_(R).

As can be seen in FIG. 26, the maximum amplitude 2601 of the phase-shift modulation φ_(m)(t) 2600 is herein equal to 2π+π/4.

Hence generated by the phase modulator 33 of the modulation chain 30, the phase-shift modulation φ_(m)(t) 2600 introduces between the two counter-propagating waves 24, 25 at the output of the SAGNAC ring interferometer 20 a phase-difference modulation Δφ_(m)(t)=φ_(m)(t)−φ_(m)(t−Δπ_(g)) as shown in FIG. 27.

It can be noted that this phase-difference modulation Δφ_(m)(t) 2700 oscillates between 4 different levels:

-   -   two high levels:         -   a first level or level 1 when Δφ_(m)(t)=π−π/4+φ_(s)         -   a second level or level 2 when Δφ_(m)(t)=π+π/4+φ_(s), and     -   two low levels:         -   a third level or level 3 when Δφ_(m)(t)=−π+π/4+φ_(s)         -   a fourth level or level 4 when Δφ_(m)(t)=−π−π/4+φ_(s).

As can be seen in FIG. 27, the phase-difference modulation Δφ_(m)(t) 2700 is hence shifted towards the high side of the value φ_(s)=−Δφ_(p) (=π/20 herein) as seen above.

It can also be noted that, at the instant t=t_(R) of the falling down of the phase-shift modulation φ_(m)(t), the phase-difference modulation Δφ_(m)(t) does not rise up (dash line 2701) but remains at its fourth level 2702 during a step duration, to thereafter rise up at the instant t_(R)+Δτ_(g) towards the high levels 1 and 2, the phase-difference modulation Δφ_(m)(t) being symmetrical relative to the falling down instant (that is to say that Δφ_(m)(t_(R)+t)=Δφ_(m)(t_(R)−t)). The alternation between high and low levels then continues until the next falling down.

To sum up, in the second particular embodiment of the invention, it has been seen on the one hand that the parameter to be measured introduces between the two counter-propagating waves a phase difference Δφ_(p)=−π/20 at the output of the SAGNAC ring interferometer 20. On the other hand, it has been seen that the counter-propagating means 120 generate a first feedback signal to produce at the output of the modulation chain 30 a first stair-step feedback modulation component φ_(cr1)(t) of step height φ_(s)=π/20 so as to introduce between the two counter-propagating waves 24, 25 a first feedback phase-difference modulation component Δφ_(cr1)(t) compensating for the phase difference Δφ_(p) due to the parameter to be measured.

Hence, it has been shown in FIG. 28:

-   -   the total phase difference Δφ_(t)(t) 2801 between the two         counter-propagating waves 24, 25 at the output of the ring         interferometer 20, this total phase difference Δφ_(t)(t) being         such that: Δφ_(t)(t)=Δφ_(p)+Δφ_(m)(t),     -   the luminous power P(Δφ_(t)) 2802 received by the detector 14 as         a function of the total phase difference Δφ_(t)(t) 2801, and     -   the modulated electrical signal S(t) 2803 delivered by the         detector 14 as a function of time t.

As the total phase difference Δφ_(t)(t) is the sum of the phase difference Δφ_(p) due to the parameter to be measured and of the phase-difference modulation Δφ_(m)(t), it will first be noted in FIG. 28 that the curve 2801 showing the total phase difference Δφ_(t)(t) as a function of time t corresponds to the curve 2700 of FIG. 27 showing the phase-difference modulation Δφ_(m)(t), this curve being shifted towards the abscissa axis of the value of the phase difference Δφ_(p) due to the parameter to be measured.

Hence, the total phase-difference modulation Δφ_(t)(t) 2801 has sequentially four different levels defining four different modulation states, which are:

-   -   State E1 when the total phase-difference modulation Δφ_(t)(t) is         Δφ₁=π−π/4=3π/4,     -   State E2 when the total phase-difference modulation Δφ_(t)(t) is         Δφ₂=π+π/4=5π/4,     -   State E3 when the total phase-difference modulation Δφ_(t)(t) is         Δφ₃=−π+π/4=−3π/4 (=Δφ₂−2π),     -   State E4 when the total phase-difference modulation Δφ_(t)(t) is         Δφ₄=−π−π/4=−5π/4 (=Δφ₁−2π).

The luminous power P(Δφ_(t)) 2802 received by the detector 14 is hence modulated following these four distinct modulation states and the modulated electrical signal S(t) 2803 delivered by the detector 14 takes sequentially four values S1, S2, S3, and S4 associated with the four modulation states E1, E2, E3, and E4, respectively, of the total phase-difference modulation Δφ_(t)(t).

As can be seen in FIG. 28, the luminous power P(Δφ_(t)) 2802 received by the detector 14 in the four modulation states E1 to E4 is the same. Indeed, the received luminous power P(Δφ_(t)) 2802 being a cosine function of the total phase difference Δφ_(t) 2801, the following relation is satisfied: P(Δφ₁)=P(Δφ₄) and P(Δφ₂)=P(Δφ₃). Moreover, the states E1 and E2 (respectively the states E3 and E4) being symmetrical relative to π (respectively relative to −π), the following relations are also satisfied: P(Δφ₁)=P(Δφ₂) and P(Δφ₃)=P(Δφ₄).

The detector 14 then delivers a modulated electrical signal S(t) 2803 such as shown in FIG. 28. This modulated electrical signal S(t) 2803 takes sequentially the four values S1, S2, S3, and S4 associated with the four modulation states E1, E2, E3, and E4, respectively. Taking into account what has been explained regarding the luminous power P(Δφ_(t)) 2802 received by the detector 14 in the four modulation states E1 to E4, these four values S1, S2, S3, and S4 taken by the modulated electrical signal S(t) 2803 are herein all identical S1=S2=S3=S4.

In particular, as for the first embodiment of the invention described hereinabove, it will also be noted that the falling down 2701 of the phase-difference modulation Δφ_(m)(t) 2700 at the instant t=t_(R) (see FIG. 27) creates no defect in the modulated electrical signal S(t) 2803 insofar as the total phase difference Δφ_(t) 2801 does not change during this falling down (Δφ_(m)(t) remaining at its low level 2702). Hence, the falling down does not disturb the measurement.

It is nevertheless to be noted in FIG. 28 that the modulated electrical signal S(t) has peaks 2804 corresponding alternately to the transitions from the modulation state E1 to the modulation state E4 and from the modulation state E3 to the modulation state E2, when the received luminous power P(Δφ_(t)) 2802 passes by a maximum at the value Δφ_(t)=0, this maximum having for value 2P₀.

These peaks 2804 are cumbersome insofar as they introduce unwanted defects in the modulated electrical signal S(t) 2803.

From the preceding situation, described in FIG. 28, where the parameter to be measured generates a phase difference Δφ_(p) that is exactly compensated thanks to the first feedback phase-difference modulation component Δφ_(cr1)(t) introduced between the two counter-propagating waves 24, 25 in the SAGNAC ring interferometer 20 by the first, stair-step, feedback phase-shift modulation component Δφ_(cr1)(t), the situation passes to that described in FIG. 29, where the phase difference Δφ_(p) is not exactly compensated by the first feedback phase-difference modulation component Δφ_(cr1)(t).

This situation can, for example, occur when the parameter to be measured varies abruptly, so that the phase difference Δφ_(p) also varies abruptly. In this case, it is necessary to wait for a few clock times 101 to come back to the situation of FIG. 27.

It will be considered in this example that the phase difference Δφ_(p) generated by the parameter is not exactly compensated for, so that the total phase difference Δφ_(t) is increased by the value π/16.

This can be shown in FIG. 29 by shifting the curve 2901 representing the total phase difference Δφ_(t) by the value π/16. This shift causes a change of the four modulation states on which is modulated the signal received by the detector 14, which is function of the luminous power P(Δφ_(t)) 2902 received by the latter.

The four levels of the total phase-difference modulation Δφ_(t) 2901 associated with the four modulation states are hence now:

-   -   For the state E1:         -   Δφ_(t)=Δφ₁+π/16=3π/4+π/16=13π/16     -   For the state E2:         -   Δφ_(t)=Δφ₂+π/16=5π/4+π/16=21π/16     -   For the state E3:         -   Δφ_(t)=Δφ₃+π/16=−3π/4+π/16=−11π/16     -   For the state E4:         -   Δφ_(t)=Δφ₄+π/16=−5π/4+π/16=−19π/16.

Hence, as can be seen in FIG. 29, the luminous power P(Δφ_(t)) 2902 received by the detector 14 in the modulation states E1 and E4 is lower, and that received in the modulation states E2 and E3 is higher.

The detector 14 then delivers a modulated electrical signal S(t) 2903 such as shown in FIG. 29. This modulated electrical signal S(t) 2903 takes sequentially the four values S1, S2, S3 and S4 associated with the four modulation states E1, E2, E3 and E4, respectively. These four values S1, S2, S3 and S4 taken by the modulated electrical signal S(t) 2903 are herein identical two by two: S1=S4 and S2=S3.

The modulated electrical signal S(t) 2903 is then digitalized by the analog/digital converter 111 that delivers and transmits a digital electric signal to the digital processing unit 112.

This digital electrical signal is also modulated and takes four digital values Σ1, Σ2, Σ3, and Σ4 according to the four modulation states E1, E2, E3, and E4 of the total phase-difference modulation Δφ_(t) 2901.

The digital processing unit 112 demodulates the digital electrical signal in phase with the second biasing phase-shift modulation component φ_(b2)(t) (cf. FIG. 25) independently of the first phase-shift modulation component φ_(m1)(t) (cf. FIG. 26).

It is meant by this that the digital processing unit 112 delivers a first demodulated digital signal Σ_(p) based on the 4 digital values Σ1, Σ2, Σ3, and Σ4 associated with the 4 modulation states E1, E2, E3, and E4, respectively, by performing a calculation operation of the type: Σ_(p)=−Σ1+Σ2+Σ3−Σ4 where the weight of each digital value in the previous expression depends on the sign of the second biasing phase-shift modulation component φ_(b2)(t), in the modulation state associated with this digital value, but does not depend on the level of the first phase-shift modulation component φ_(m1)(t), in this modulation state.

The digital processing unit 112 hence produces a first demodulated digital signal Σ_(p) depending on the phase-shift Δφ_(p) and representative of the value of the parameter to be measured in the SAGNAC ring interferometer 20.

In a closed-loop operation, the first demodulated digital signal Σ_(p) serves as an error signal to control the total phase difference Δφ_(t) to zero by compensating for the non-reciprocal phase-shift Δφ_(p) with the opposite phase-shift Δφ_(cr1) introduced by the phase modulator 33 controlled by the feedback means 120.

This phase-shift Δφ_(cr1) being generated through the same modulation chain 30 as the biasing modulation φ_(b1), the control of the modulation chain 30, whose operation is detailed hereinafter, hence allows to have a steady and controlled measurement of Δφ_(cr1), and hence finally of Δφ_(p), which is opposite thereto and which is the parameter that is desired to be measured.

FIG. 30 shows the case of a fibre-optic measurement device 10 according to the second embodiment of the invention, in which the transfer function of the modulation chain 30 in incorrectly adjusted.

In practice, the transfer function, which depends on the characteristics of both the digital/analog converter 31 via its analog reference voltage and the amplifier 32 via its variable gain G, may undergo variations as a function of the measurement conditions, for example the operating temperature of the device 10 or the electrical drift of certain electronic components of the electronic means 100. Generally, the parameters influencing the transfer function cause low and slow variations of the latter, so that the gain control means 150 operate easily and rapidly so as to keep adjusted the transfer function of the modulation chain 30.

The fact that the transfer function of the modulation chain 30 is incorrectly adjusted translates at the level of the total phase difference Δφ_(t) by a dilatation of the curve of FIG. 28 representing the total phase Δφ_(t) so that the total phase difference Δφ_(t) 3001 is similar to that shown in FIG. 30.

Hence, this dilatation (herein of ratio 16/15) causes a change of the four modulation states E1, E2, E3, and E4, on which is modulated the signal received by the detector 14, which is function of the received luminous power P(Δφ_(t)) 3002 at the output of the SAGNAC ring interferometer 20.

The four levels of the total phase-difference modulation Δφ_(t) 3001 associated with the four modulation states in the example of FIG. 30 are hence:

-   -   For the state E1:         -   Δφ_(t)=(16/15)·Δφ₁=4π/5     -   For the state E2:         -   Δφ_(t)=(16/15)·Δφ₂=4π/3     -   For the state E3:         -   Δφ_(t)=(16/15)·Δφ₃=−4π/5     -   For the state E4:         -   Δφ_(t)=(16/15)·Δφ₄=−4π/3.

Hence, the luminous power P(Δφ_(t)) 3002 received by the detector 14 in the modulation states E1 and E3 is identical, but lower than the received luminous power when the transfer function of the modulation chain 30 is correctly adjusted, as in FIGS. 28 and 29.

Likewise, the luminous power P(Δφ_(t)) 3002 received by the detector 14 in the modulation states E2 and E4 is identical, but higher than the received luminous power when the transfer function of the modulation chain 30 is correctly adjusted, as in FIGS. 28 and 29.

The detector 14 then delivers a modulated electrical signal S(t) 3003 such as shown in FIG. 30. This modulated electrical signal S(t) 3003 takes sequentially four values S1, S2, S3, and S4 associated with the four modulation states E1, E2, E3, and E4, respectively. These four values are herein identical two by two: S1=S3 and S2=S4.

The four values Σ1, Σ2, Σ3, and Σ4 of the digital electrical signal associated with the four modulation states E1, E2, E3 and E4, respectively, being also identical two by two, with Σ1=Σ3 and Σ2=Σ4, the first demodulated digital signal Σ_(p), calculated by the operation Σ_(p)=−Σ1+Σ2+Σ3−Σ4, is hence zero.

Besides, the digital electrical signal delivered by the analog/digital converter 111 is transmitted to the gain control means 150 such as shown in FIG. 23.

The gain control means 150 demodulate the digital electric signal so as to provide a signal function of the transfer function of the modulation chain 30.

More precisely, the other digital processing unit of the gain control means 150 operate a calculation operation of the type: Σ_(G)=Σ1−Σ2+Σ3−Σ4, so as to produce a second demodulated digital signal Σ_(G) independent of the phase difference Δφ_(p) generated by the parameter to be measured, but significant of the transfer function of the modulation chain 30.

In particular, in the case shown in FIG. 30, the second demodulated digital signal Σ_(G) is non-zero, the transfer function of the modulation chain 30 being incorrectly adjusted.

The second demodulated digital signal Σ_(G) then serves as an error signal for a control loop of the transfer function of the modulation chain 30.

For that purpose, the second demodulated digital signal Σ_(G) is filtered by a control-loop digital integrator filter that then feeds the digital/analog converter 31 to control its analog reference voltage or the amplifier 32 to control its variable gain G.

Hence, the transfer function of the modulation chain 30 is kept correctly adjusted between the value of the digital control signal and the value of the phase-shift modulation effectively applied by the phase modulator 33.

It will be observed that, in the case of FIGS. 28 and 29, the second demodulated digital signal Σ_(G) is zero because the transfer function of the modulation chain 30 is correctly adjusted.

Indeed, in this case:

-   -   Σ1=Σ4, the received luminous power P(Δφ_(t)) received in the         state E1 and in the state E4 being the same, and     -   Σ2=Σ3, the received luminous power P(Δφ_(t)) received in the         state E2 and in the state E3 being the same.

3^(rd) Embodiment

A third embodiment of the invention will now be detailed with reference to FIGS. 31 to 35. In this embodiment:

-   -   a₁=4 and k₁=0, i.e. the first biasing phase-shift modulation         component φ_(b1)(t) is a square pulse-wave modulation of         amplitude π/4 between a high level +π/8 and a low level −π/8 and         periodic at a first phase-shift modulation frequency f_(b1)         equal to the proper frequency f_(p) of the SAGNAC ring         interferometer 20, and     -   Δφ_(p)=−π/40 so that the first feedback phase-shift modulation         component φ_(m1)(t) is an ascending stair-step modulation of         step height φ_(s)=−Δφ_(p)=π/40 compensating for the phase         difference Δφ_(p) due to the parameter to be measured.

Hence, according to the invention, the first phase-shift modulation component φ_(m1)(t) 3100 is such as shown in FIG. 31. It has an ascending pulse-wave modulation shape, falls down by 2π/4 (=π/2) at the instant t=t_(R), and has a maximum amplitude lower than 2π/4 (=π/2).

Furthermore, in this third embodiment of the invention, the biasing means 120 generate a second biasing signal producing at the output of the modulation chain 30 a second biasing phase-shift modulation component φ_(b2)(t) 3200, this second biasing phase-shift modulation component φ_(b2)(t) 3200 being (cf. FIG. 32):

-   -   a square pulse-wave modulation of amplitude π/a₂=π, with herein         a₂=1≠a₁=4, between a high level +π/2 and a low level −π/2,     -   periodic at a second phase-shift modulation frequency f_(b2)         such that f_(b2)=(2k₂+1)f_(p)=f_(p), with k₂=k₁=0 so that         (2k₁+1)=1 and (2k₂+1)=1 are multiple of each other,     -   in quadrature with respect to the first biasing phase-shift         modulation component φ_(b1)(t).

It has been shown in FIG. 33 the phase-shift modulation φ_(m)(t) 3300 resulting, for the third embodiment, from the sum of the first phase-shift modulation component φ_(m1)(t) 3100 and of the second phase-shift modulation component φ_(b2)(t) 3200.

It can be seen in FIG. 33 that, taking into account that the first feedback phase-shift modulation component φ_(cr1)(t) is an ascending modulation, the first phase-shift modulation component φ_(m1)(t) 3100 falls down by 2π/4 according to the above-described rule, at the falling down instant t=t_(R). Likewise, the resulting phase-shift modulation φ_(m)(t) 3300 also falls down at the same instant t=t_(R).

As can be seen in FIG. 33, the maximum amplitude 3301 of the phase-shift modulation φ_(m)(t) 3300 is herein equal to 2(π/4)+π.

Hence generated by the phase modulator 33 of the modulation chain 30, the phase-shift modulation φ_(m)(t) introduces between the two counter-propagating waves 24, 25 at the output of the SAGNAC ring interferometer 20 a phase-difference modulation Δφ_(m)(t)=φ_(m)(t)−φ_(m)(t−Δφ_(g)) such as shown in FIG. 34.

It can be observed, for this third embodiment, that this phase-difference modulation Δφ_(m)(t) 3400 oscillates between 4 different levels:

-   -   two high levels:         -   a first level or level 1 when Δφ_(m)(t)=π−π/4+φ_(s)         -   a second level or level 2 when Δφ_(m)(t)=π+π/4+φ_(s), and     -   two low levels:         -   a third level or level 3 when Δφ_(m)(t)=−π+π/4+φ_(s)         -   a forth level or level 4 when Δφ_(m)(t)=π−π/4+φ_(s).

As can be seen in FIG. 34, the phase-difference modulation Δφ_(m)(t) 3400 is hence shifted towards the high side of the value φ_(s)=−Δφ_(p) (=π/40 herein) as seen above.

Moreover, it can be observed that, at the instant t=t_(R) of the falling down of the phase-shift modulation φ_(m)(t), the phase-difference modulation Δφ_(m)(t) does not rise up (dash line 3401) but remains at its first level 3402 during half a step duration, to then fall down at the instant t_(R)+(Δτ_(g)/2) towards the third level 3403, the phase-difference modulation Δφ_(m)(t) being symmetrical with respect to the instant of the falling down (i.e. that Δφ_(m)(t_(R)+t)=Δφ_(m)(t_(R)−t)). The alternation between high levels and low levels then continue until the next falling down.

To sum up, in the third particular embodiment of the invention, it has been seen on the one hand that the parameter to be measured introduces between the two counter-propagating waves a phase difference Δφ_(p)=−π/40 at the output of the SAGNAC ring interferometer 20. On the other hand, it has been seen that the feedback means 120 generate a first feedback signal to produce at the output of the modulation chain 30 a first stair-step feedback phase-shift modulation component φ_(cr1)(t) of step height φ_(s)=π/40 so as to introduce between the two counter-propagating waves 24, 25 a first feedback phase-difference modulation component Δφ_(cr1)(t) compensating for the phase difference Δφ_(p) due to the parameter to be measured.

For the third embodiment of the invention, it has hence been shown in FIG. 35:

-   -   the total phase difference Δφ_(t)(t) 3501 between the two         counter-propagating waves 24, 25 at the output of the ring         interferometer 20, this total phase difference Δφ_(t)(t) being         such that: Δφ_(t)(t)=Δφ_(p)+Δφ_(m)(t),     -   the luminous power P(Δφ_(t)) 3502 received by the detector 14 as         a function of the total phase difference Δφ_(t)(t), and     -   the modulated electrical signal S(t) 3503 delivered by the         detector 14 as a function of time t.

As the total phase difference Δφ_(t)(t) 3501 is the sum of the phase difference Δφ_(p) due to the parameter to be measured and of the phase-difference modulation Δφ_(m)(t) 3400, it will also be observed in FIG. 35 that the curve 3501 representing the total phase difference Δφ_(t)(t) as a function of time t corresponds to the curve 3400 of FIG. 34 representing the phase-difference modulation Δφ_(m)(t), this curve being shifted towards the abscissa axis by the value of the phase difference Δφ_(p) due to the parameter to be measured.

Hence, the total phase-difference modulation Δφ_(t)(t) 3501 has sequentially four different levels defining four different modulations states, which are:

-   -   State E1 when the total phase-difference modulation Δφ_(t)(t) is         Δφ₁=π−π/4=3π/4,     -   State E2 when the total phase-difference modulation Δφ_(t)(t) is         Δφ₂=π+π/4=5π/4,     -   State E3 when the total phase-difference modulation Δφ_(t)(t) is         Δφ₃=−π+π/4=−3π/4 (=Δφ₂−2π),     -   State E4 when the total phase-difference modulation Δφ_(t)(t) is         Δφ₄=−π−π/4=−5π/4 (=Δφ₁−2π).

The luminous power P(Δφ_(t)) 3502 received by the detector 14 is hence modulated according to the four distinct modulation states and the modulated electric signal S(t) 3503 delivered by the detector 14 takes sequentially four values S1, S2, S3, and S4 associated with the four modulation states E1, E2, E3, and E4, respectively, of the total phase-difference modulation Δφ_(t)(t) 3501.

As can be seen in FIG. 28, the luminous power P(Δφ_(t)) 3502 received by the detector 14 in the four modulation states E1 to E4 is the same. Indeed, the received luminous power P(Δφ_(t)) 3502 being a cosine function of the total phase difference Δφ_(t) 3501, the following relations are satisfied: P(Δφ₁)=P(Δφ₄) and P(Δφ₂)=P(Δφ₃). Moreover, the states E1 and E2 (respectively the states E3 and E4) being symmetrical with respect to π (respectively with respect to −π), the following relations are also satisfied: P(Δφ₁)=P(Δφ₂) and P(Δφ₃)=P(Δφ₄).

The detector 14 then delivers a modulated electric signal S(t) 3503 as shown in FIG. 35. This modulated electric signal S(t) 3503 takes sequentially the four values S1, S2, S3, and S4 associated with the four modulation states E1, E2, E3, and E4, respectively. Taking into account what have been explained regarding the luminous power P(Δφ_(t)) 3502 received by the detector 14 in the four modulation states E1 to E4, these four values S1, S2, S3, and S4 taken by the modulated electrical signal S(t) 3503 are herein all identical: S1=S2=S3=S4.

As herein-above, it can be observed that the falling down of the phase-difference modulation Δφ_(m)(t) 3400 at the instant t=t_(R) (see FIG. 34) creates no defect in the modulated electrical signal S(t) 3503 of FIG. 35 insofar as the total phase difference Δφ_(t) 3501 does not change during this falling down (Δφ_(m)(t) remaining at its high level 3402). Hence, the falling down does not disturb the measurement.

4^(th) Embodiment

A fourth embodiment of the invention will now be detailed with reference to FIGS. 36 to 40. In this embodiment:

-   -   a₁=1 and k₁=0, i.e. the first biasing phase-shift modulation         component φ_(b1)(t) is a square pulse-wave modulation of         amplitude π between a high level +π/2 and a low level −π/2 and         periodic at a first biasing modulation frequency f_(b1) equal to         the proper frequency f_(p) of the SAGNAC ring interferometer 20,         and     -   Δφ_(p)=−3π/40 so that the first feedback phase-shift modulation         component φ_(cr1)(t) is an ascending stair-step modulation of         step height φ_(s1)=[a₂/(a₂−1)](−Δφ_(p))=π/10 with a₂=4≠a₁=1.

Hence, in this fourth embodiment of the invention, the first phase-shift modulation component φ_(m1)(t) 3600 is such as shown in FIG. 36. It has an ascending pulse-wave modulation shape, falls down by 2π at the instant t=t_(R), and has a maximum amplitude lower than 2π.

Moreover, in this fourth embodiment of the invention, the biasing means 120 generate a second biasing signal producing at the output of the modulation chain 30 a second biasing phase-shift modulation component φ_(b2)(t), this second biasing phase-shift modulation component φ_(b2)(t) being:

-   -   a square pulse-wave modulation of amplitude π/a₂=π/4 (hence         a₂=4, as described above) between a high level +π/8 and a low         level −π/8,     -   periodic at a second biasing modulation frequency f_(b2) such         that f_(b2)=f_(b1)=(2k₁+1)f_(p)=f_(p), because herein k₁=0 (see         above),     -   in lagging quadrature relative to the first biasing phase-shift         modulation component φ_(b1)(t).

It will be defined herein that the second biasing phase-shift modulation component φ_(b2)(t) is in lagging quadrature relative to the first biasing phase-shift modulation component φ_(b1)(t) when a transition of the first biasing phase-shift modulation component φ_(b1)(t) from a high level to a low level occurs when the second biasing phase-shift modulation component φ_(b2)(t) is at a high level. By symmetry, a transition of the first biasing phase-shift modulation component φ_(b1)(t) from a low level to a high level occurs when the second biasing phase-shift modulation component φ_(b2)(t) is at a low level.

In this fourth embodiment of the invention, the feedback means 120 generate a second feedback signal, producing at the output of the modulation chain a second feedback phase-shift modulation component φ_(cr2)(t) which is:

-   -   a stair-step modulation, each step having a duration Δτ_(g) and         a height φ_(s2)=[1/(a₂−1)](−Δφ_(p))=(1/3)·(3π/40)=π/40,     -   in lagging quadrature relative to the first feedback phase-shift         modulation component φ_(cr1)(t).

So generated, the second feedback phase-shift modulation component φ_(cr2)(t) introduces a second feedback phase-difference modulation component Δφ_(r2)(t)=φ_(cr2)(t)−φ_(cr2)(t−Δτ_(g)) between the two counter-propagating waves 24, 25 propagating in the SAGNAC ring interferometer 20.

The heights φ_(S1) and φ_(s2) of the first and second feedback phase-shift modulation components φ_(cr1)(t) and φ_(cr2)(t) are such that the difference between the first feedback phase-difference modulation component Δφ_(cr1)(t) and the second feedback phase-difference modulation component Δφ_(cr2)(t) compensates for the phase difference Δφ_(p).

Indeed, the feedback phase-difference modulation Δφ_(cr)(t), defined as the difference between the first feedback phase-difference modulation component Δφ_(cr1)(t) and the second feedback phase-difference modulation component Δφ₂(t), is a stair-step modulation, each step having a height φ_(s)=φ_(s1)−φ_(s2)=π/10−π/40=3π/40=Δφ_(p).

Besides, in this fourth embodiment, the control means 140 for controlling the modulation chain 30 process the second biasing signal and second feedback signal to deliver at least one second control signal at the input of the modulation chain 30.

This second control signal then produces at the output of the modulation chain 30 a second phase-shift modulation component φ_(m2)(t) which is the sum of the second biasing phase-shift modulation component φ_(b2)(t) and the second feedback phase-shift modulation component φ_(cr2)(t), so that: φ_(m2)(t)=φ_(b2)(t)+φ_(cr2)(t).

Furthermore, according to this fourth embodiment, the control means 140 are arranged so that the second phase-shift modulation component φ_(m2)(t) operates a transition of twice the amplitude of the second biasing phase-shift modulation component φ_(b2)(t), i.e. herein 2π/a₂=2π/4=π/2 (with a₂=4), when its level exceeds the amplitude of the second biasing phase-shift modulation component φ_(b2)(t), i.e. π/a₂=π/4.

Hence, it has been shown in FIG. 37 the curve representing this second phase-shift modulation component φ_(m2)(t) 3700. Being formed similarly to the first phase-shift modulation component φ_(m1)(t) 3600, the second phase-shift modulation component φ_(m2)(t) 3700 is also a pulse-wave modulation, herein ascending. This modulation falls down at the instant t=t′_(R)=t_(R)+Δτ_(g)/2, φ_(m2)(t) being in lagging quadrature relative to φ_(m1)(t).

Mathematically, the relation that links the first phase-shift modulation component φ_(m1)(t) 3600 to the second phase-shift modulation component φ_(cr2)(t) 3700 is herein the following: φ_(m2)(t)=(1/a₂)·φ_(m1)(t−Δτ_(g)/2).

Generally, in this fourth embodiment, when:

-   -   the first phase-shift modulation component φ_(m1)(t) is a         pulse-wave modulation, the width of each pulse of which is equal         to Δτ_(g)/(2k₁+1), the first biasing phase-shift modulation         component φ_(b1)(t) being a periodic modulation at a first         biasing modulation frequency f_(b1) such that         f_(b1)=(2k₁+1)f_(p) (f_(p)=1/2Δτ_(g) being the proper frequency         of the ring interferometer 20), and     -   the second phase-shift modulation component φ_(m2)(t) is a         pulse-wave modulation, the width of each pulse of which is equal         to Δτ_(g)/(2k₁+1), the second biasing phase-shift modulation         component φ_(b1)(t) being a periodic modulation at a second         biasing modulation frequency f_(b2) such that         f_(b2)=f_(b1)=(2k₁+1)f_(p),         the mathematical relation that links the first phase-shift         modulation component φ_(m1)(t) to the second phase-shift         modulation component φ_(m2)(t) is then the following:         φ_(m2)(t)=(1/a₂)·φ_(m1)(t−[Δτ_(g)/2(2k₁+1)]).

A phase-shift modulation φ_(m)(t) is then defined as the difference between the first phase-shift modulation component φ_(m1)(t) and the second phase-shift modulation component φ_(m2)(t) such that φ_(m)(t)=φ_(m1)(t)−φ_(m2)(t).

It has hence been shown in FIG. 38 the resulting phase-shift modulation φ_(m)(t) 3800 for this fourth embodiment.

It can be observed in this figure that the phase-shift modulation φ_(m)(t) 3800 is an ascending, “four state” modulation, having:

-   -   a falling down at the instant t=t_(R) of the falling down of the         first phase-shift modulation component φ_(m1)(t) 3600, this         falling down having the same amplitude, i.e. 2π, and     -   a rising up at the instant t=t′_(R)=t_(R)+Δτ_(g)/2 of the         falling down of the second phase-shift modulation component         φ_(m2)(t) 3700, this rising up having the same amplitude as the         falling down, i.e. 2π/4.

The phase-shift modulation φ_(m)(t) 3800 operates a rising up at the instant t=t′_(R) rather than a falling down as the second phase-shift modulation component φ_(m2)(t) 3700 because the contribution of the second phase-shift modulation component φ_(m2)(t) 3700 is added negatively to the phase-shift modulation φ_(m)(t) 3800, being equal to φ_(m1)(t)−φ_(m2)(t).

So formed, the phase-shift modulation φ_(m)(t) 3800 has a maximum amplitude strictly lower than 2π, as can be verified in FIG. 38. The excursion of the modulation chain is hence limited and the effects of the non-linearities of the latter are reduced.

So generated by the phase modulator 33 of the modulation chain 30, the phase-shift modulation φ_(m)(t) 3800 introduces between the two counter-propagating waves 24, 25 at the output of the SAGNAC ring interferometer 20 a phase-difference modulation Δφ_(m)(t)=φ_(m)(t)−φ_(m)(t−Δτ_(g)) such as shown in FIG. 39.

It is observed, for this fourth embodiment, that the phase-difference modulation Δφ_(m)(t) 3900 also oscillates between 4 different levels:

-   -   two high levels:         -   a first level when Δφ_(m)(t)=π−π/4+φ_(s),         -   a second level when Δφ_(m)(t)=π+π/4+φ_(s), and     -   two low levels:         -   a third level when Δφ_(m)(t)=−π+π/4+φ_(s)         -   a fourth level when Δφ_(m)(t)=−π−π/4+φ_(s).

As can be seen in FIG. 39, the phase-difference modulation Δφ_(m)(t) 3900 is hence shifted towards the high side of the value φ_(s)=−Δφ_(p) (=3π/40 herein) as seen above. Moreover, its amplitude is herein equal to 2π+2(π/4)=2π+π/2.

Besides, it can be observed that at the instant t=t_(R) of the falling down of the phase-shift modulation φ_(m)(t) 3800, the phase-difference modulation Δφ_(m)(t) 3900 does not rise up but remains at its third level 3901 during half a step duration Δτ_(g)/2. Then, at the instant t=t′_(R)=t_(R)+Δτ_(g)/2 of the falling down of the second phase-shift modulation component φ_(m2)(t), the phase-difference modulation Δφ_(m)(t) still remains at its third level 3902 during half a step duration Δτ_(g)/2.

The phase-difference modulation Δφ_(m)(t) then rises up towards the levels to resume its alternations between high levels and low levels until the next transition.

For the fourth embodiment of the invention, it has finally been shown in FIG. 40:

-   -   the total phase difference Δφ_(t)(t) 4001 between the two         counter-propagating waves 24, 25 at the output of the ring         interferometer 20, this total phase difference Δφ_(t)(t) 4001         being such that: Δφ_(t)(t)=Δφ_(p)+Δφ_(m)(t),     -   the luminous power P(Δφ_(t)) 4002 received by the detector 14 as         a function of the total phase difference Δφ_(t)(t) 4001, and     -   the modulated electric signal S(t) 4003 delivered by the         detector 14 as a function of time t.

As hereinabove, it can be observed that neither the falling down at the instant t=t_(R), nor the rising up at the instant t=t′_(R) of the phase-difference modulation Δφ_(m)(t) 3900 (see FIG. 39) creates a defect in the modulated electric signal S(t) 4003 of FIG. 40, insofar as the total phase difference Δφ_(t) 4001 does not change during this falling down or this rising up (Δφ_(m)(t) remaining at its third level 3901 and 3902). Hence, neither the falling down, nor the rising up, disturbs the measurement.

The measurement device according to the invention is particularly well adapted to the realization of a gyrometer. In this case, the parameter to be measured is a component of the rotational speed of the ring interferometer.

This gyrometer hence advantageously enters into the making of navigation or inertial-stabilization systems.

Such an arrangement is also well adapted to the realization of a device for measuring magnetic fields or electric currents, using advantageously the FARADAY effect. 

The invention claimed is:
 1. A fibre-optic measurement device (10) in which a parameter to be measured generates a phase difference Δφ_(p) between two counter-propagating waves (24, 25), comprising: a light source (11), a fiber-optic SAGNAC ring interferometer (20), including a coil (21) and a splitting element (23), in which said two counter-propagating waves (24, 25) propagate, said ring interferometer (20) having a proper frequency f_(p), an electromagnetic radiation detector (14), receiving the luminous power exiting from said ring interferometer (20) and delivering a modulated electrical signal representative of the luminous power, which is function of the total phase difference Δφ_(t) between said two counter-propagating waves (24, 25) at the output of said ring interferometer (20), a modulation chain (30) adapted to modulate said luminous power exiting from said ring interferometer (20), said modulation chain (30) including at least one phase modulator (33) placed in said ring interferometer (20) and adapted to generate at the output of said modulation chain (30) a phase-shift modulation φ_(m)(t), introducing between said two counter-propagating waves a phase-difference modulation Δφ_(m)(t) such that: Δφ_(m)(t)=φ_(m)(t)−φ_(m)(t−Δτ_(g)), Δτ_(g)=1/(2 f_(p)) being the transit time difference between said two counter-propagating waves (24, 25) determined between said phase modulator (33) and said splitting element (23), and an electronic module (100) comprising: i) signal processing means (110) including: an analog/digital converter (111) digitizing said modulated electrical signal received from the detector (14) and representative of said luminous power received by said detector (14) to deliver a digital electrical signal, and a digital processing unit (112) adapted to process said digital electrical signal to deliver a signal function of said phase difference Δφ_(p) and of said parameter to be measured, ii) a biasing module (130) providing a first biasing signal, producing at the output of the modulation chain (30), a first, square pulse-wave, biasing phase-shift modulation component φ_(b1)(t) of amplitude π/a₁,a₁ being a non-zero real number, periodic at a first biasing modulation frequency f_(b1) such that f_(b1)=(2k₁+1)f_(p), k₁ being a natural number and f_(p) being the proper frequency, iii) feedback means (120) adapted to process said signal function of said phase difference Δφ_(p) to generate a first feedback signal, producing at the output of the modulation chain (30), a first, stair-step, feedback phase-shift modulation component φ_(cr1)(t), each step having a duration Δτ_(g)/(2k₁+1), said first feedback phase-shift modulation component φ_(cr1)(t) introducing between said two counter-propagation waves (24, 25) a first feedback phase-difference modulation component Δφ_(cr1)(t)=φ_(cr1)(t)−φ_(cr1)(t−Δτ_(g)) that is function of said phase difference Δφ_(p), and iv) a control module (140) for controlling said modulation chain (30), the control module (140) receiving said first biasing signal from the biasing module (130) and said first feedback signal from said feedback means (120), the control module (140) being adapted to process said first biasing signal and said first feedback signal to deliver at least one first control signal at the input of said modulation chain (30), the at least one first control signal producing at the output of the modulation chain (30) a first phase-shift modulation component φ_(m1)(t) that is the phase sum of said first biasing phase-shift modulation component φ_(b1)(t) and of said first feedback phase-shift modulation component φ_(cr1)(t), such that φ_(m1)(t)=φ_(b1)(t)+φ_(cr1)(t), wherein the control module (140) is arranged so that said first phase-shift modulation component φ_(m1)(t) operates a transition of twice the amplitude of the first biasing phase-shift modulation component φ_(b1)(t) when the level of said first phase-shift modulation component φ_(m1)(t) exceeds the amplitude of the first biasing phase-shift modulation component φ_(b1)(t).
 2. The fibre-optic measurement device (10) according to claim 1, wherein said first feedback phase-shift modulation component φ_(cr1)(t) has stair steps of height −Δφ_(p)/(2k₁+1), such that said first feedback phase-difference modulation component Δφ_(cr1)(t) is such that Δφ_(cr1)(t)=−Δφ_(p), to compensate for said phase difference Δφ_(p) due to the parameter to be measured.
 3. The fibre-optic measurement device (10) according to claim 2, wherein said biasing module (130) is adapted to generate a second biasing signal, producing at the output of the modulation chain (30) a second component of biasing phase-shift modulation φ_(b2)(t), said second biasing phase-shift modulation component φ_(b2)(t) being: a square pulse-wave modulation of amplitude π/a₂,a₂ being a non-zero real number different from a₁, periodic at a second biasing modulation frequency f_(b2) such that f_(b2)=(2k₂+1)f_(p), k₂ being a natural number such that (2k+1) and (2k₂+1) are multiples of each other, and f_(p) being the proper frequency, in quadrature relative to the first biasing phase-shift modulation component φ_(b1)(t).
 4. The fibre-optic measurement device (10) according to claim 3, wherein a₁=1.
 5. The fibre-optic measurement device (10) according to claim 4, also comprising a gain-control module (150) that controls the gain of said modulation chain (30) allowing to keep adjusted the transfer function of said modulation chain (30).
 6. The fibre-optic measurement device (10) according to claim 3, wherein a₂=1.
 7. The fibre-optic measurement device (10) according to claim 6, also comprising a gain-control module (150) that controls the gain of said modulation chain (30) allowing to keep adjusted the transfer function of said modulation chain (30).
 8. The fibre-optic measurement device (10) according to claim 3, also comprising a gain-control module (150) that controls the gain of said modulation chain (30) to keep adjusted the transfer function of said modulation chain (30).
 9. The fibre-optic measurement device (10) according to claim 3, wherein k₂=0.
 10. The fibre-optic measurement device (10) according to claim 1, wherein, a₁=1, said first feedback phase-shift modulation component φ_(cr1)(t) has stair steps of height [a₂/(a₂−1)][−Δφ_(p)/(2k₁+1)], a₂ being a real number strictly higher than a₁=1, said biasing module (130) is adapted to generate a second biasing signal producing at the output of the modulation chain (30) a second biasing phase-shift modulation component φ_(b2)(t), said second biasing phase-shift modulation component φ_(b2)(t) being: a square pulse-wave modulation of amplitude π/a₂, periodic at a second biasing modulation frequency f_(b2) such that f_(b2)=f_(b1)=(2k₁+1) f_(p), f_(b1) being the first biasing modulation frequency and f_(p) being the proper frequency, and in lagging quadrature relative to the first biasing phase-shift modulation component φ_(b1)(t), said feedback means (120) are adapted to generate a second feedback signal, producing at the output of the modulation chain a second feedback phase-shift modulation component φ_(cr2)(t), said second feedback phase-shift modulation component φ_(cr2)(t) being: a stair-step modulation, each step having a duration Δτ_(g)/(2k₁+1), and a height [1/(a₂−1)][−Δφ_(p)/(2k₁+1)], in lagging quadrature relative to the first feedback phase-shift modulation component φ_(cr1)(t), and said second feedback phase-shift modulation component φ_(cr2)(t) introducing a second feedback phase-difference modulation component Δφ_(cr2)(t)=φ_(cr2)(t)−φ_(cr2)(t−Δτ_(g)) between said two counter-propagating waves (24, 25), such that the difference between the first feedback phase-difference modulation component Δφ_(cr1)(t) and the second feedback phase-difference modulation component Δφ_(cr2)(t) compensates for the phase difference Δφ_(p) said control module (140) is adapted to process said second biasing signal and said second feedback signal to deliver at least one second control signal at the input of said modulation chain (30), producing at the output of the modulation chain (30) a second phase-shift modulation component φ_(m2)(t) that is the sum of said second biasing phase-shift modulation component φ_(b2)(t) and said second feedback phase-shift modulation component Δφ_(cr2)(t), so that φ_(m2)(t)=φ_(b2)(t)+φ_(cr2)(t), and the control module (140) is arranged so that said second phase-shift modulation component φ_(m2)(t) operates a transition of twice the amplitude of the second biasing phase-shift modulation component φ_(b2)(t) when its level exceeds the amplitude of the second biasing phase-shift modulation component φ_(b2)(t), the phase-shift modulation φ_(m)(t) being equal to the difference between the first phase-shift modulation component φ_(m1)(t) and the second phase-shift modulation component φ_(m2)(t), so that φ_(m)(t)=φ_(m1)(t)−φ_(m2)(t).
 11. The fibre-optic measurement device (10) according to claim 1, wherein k₁=0.
 12. The fiber-optical measurement device (10) according to claim 1, wherein said fiber-optic measurement device is a gyrometer, the parameter to be measured being a component of the rotational speed of the ring interferometer (20). 